一种简单、有效的适于PCR操作的放线菌DNA提取方法

目的:利用改良酶法发展了一种从微量(几百微升)发酵液中快速安全的提取放线菌基因组DNA的方法。方法:利用溶菌酶破壁,蛋白酶K和SDS除蛋白,成功提取较高质量的放线菌基因组DNA,所得的DNA可作为PCR反应的模板进行16SrRNA等基因有效扩增。结果:能从海绵和土壤分离的放线菌中成功提取基因组DNA。结论:该方法操作简单、费用低廉、不使用酚、氯仿等有毒害作用有机试剂,非常适于长期从事放线菌操作的研究人员。为大量放线菌菌株的快速鉴别、高通量筛选和系统分类研究创造了条件。     

宏基因组学挖掘新型生物催化剂的研究进展

微生物蕴藏着大量具有工业应用潜力的生物催化剂。然而,传统培养方法只能从环境中获得不到1%的微生物。宏基因组学是通过提取某一特定环境中的所有微生物基因组DNA、构建基因组文库并对文库进行筛选,寻找和发现新的功能基因的一种方法。它绕过了微生物分离培养过程,成为研究环境样品中不可培养微生物的有力手段。因此,从宏基因组中挖掘新型生物催化剂一直倍受生物学家的关注。以下主要对宏基因组文库的样品来源、DNA提取方法、文库的构建和筛选策略的选择这4个方面的研究状况进行了综述,列举了近年来利用宏基因组技术所获得的新型生物催化剂,并对其今后的研究方向提出了展望。     

红树林土壤总DNA不同提取方法比较研究

获得高浓度、大片段、无偏好的土壤微生物总DNA是土壤微生物分子生态学研究和宏基因组文库构建的基础。本研究采用了5种方法从红树林土壤中提取DNA,并对5种方法提取出的DNA的质量和产量进行比较评价。结果表明,5种方法均可从土壤中提取到DNA,但不同方法提取到DNA的产量和质量存在明显差异。Bio101FastPrep?SPINKit(forSoil)抽提到的DNA得率最高,适合分子生态学研究;SDS-GITC-PEG法提取的DNA纯度最高,所得到的DNA片段较大(>48kb),有利于构建宏基因组文库。     

漠黄梅共生菌藻宏基因组文库的构建

为了从耐旱地衣漠黄梅的共生菌藻基因组中筛选功能基因,并为蛋白质类药物的基因筛选提供平台,采用改进的CTAB方法提取其总DNA,用Sau3AⅠ限制性内切酶部分酶切基因组DNA,以质粒pUC19为载体,转入大肠杆菌DH5α中,构建了漠黄梅共生菌藻的宏基因组文库。该文库包含了4.8×105个重组子,插入片段的平均大小为4kb,覆盖漠黄梅菌藻的整个基因组4次。     

一种简单有效且适于土壤微生物多样性分析的DNA提取方法

参照Zhou[11]的方法进行了改进,获得了一种简单、有效的DNA提取方法.此方法操作简单、从大量样品改为小量样品的提取,利用高浓度的PEG沉淀,不作回收纯化,所提DNA片段较大,在23 kb以上,每克土的DNA提取量从3.74～15.28 μg,OD260/OD230比值在0.89～1.21范围内,用真菌和细菌核糖体特异性引物进行PCR扩增,均获得较好的结果,DGGE图谱显示丰富性较高,可用于细菌多样性和真菌多样性的分析.此方法能够从4种不同性质土壤中提取出DNA,但提取盐渍土壤和碱性土壤的效果更好一些,为土壤微生物群落结构的多样性分析奠定良好的基础.     

土壤微生物总DNA提取方法的优化

【目的】土壤中未培养微生物约占总量的99%,这就意味着绝大多数微生物资源还未得到开发和利用。本研究通过优化土壤微生物总DNA的提取方法,获得较高质量的DNA,为后期研究土壤微生物的多样性及构建大插入片段的宏基因组文库奠定基础。【方法】通过综合比较已报道的微生物DNA提取方法的优缺点,我们设计出一种新的提取方案。对提取过程中的几个关键步骤进行了优化,包括联合使用SDS-CTAB和溶菌酶一起来破细胞,利用氯仿除蛋白,使用PVPP柱纯化DNA等。比较分析了优化后的方法和3种已报道方法所获得的土壤总DNA的产量、纯度及片段大小。【结果】优化后的方法所获得的土壤DNA质量明显有所提高:每克土壤最高能提取95μg DNA,A260/A280和A260/A230比值更接近理想水平,PCR扩增能够得到明显的目标条带,DNA片段最大能达到100 kb左右。【结论】通过比较分析,最终确立了一种较理想的土壤微生物总DNA提取方法,为更好地开发利用土壤未培养微生物资源提供了有力工具。     

宏基因组学:土壤微生物研究的新策略

土壤中多数微生物不可培养,这限制了微生物资源的开发利用。宏基因组学方法在开发和利用不可培养微生物资源方面有巨大潜力,可以将其运用到土壤微生物学研究中。对土壤宏基因组DNA的提取、宏基因组文库的构建和筛选等方面的研究现状和进展进行了简要综述。     

从土壤中提取DNA方法比较

设计并比较了3种直接从土壤中提取DNA的方法。试验结果表明:3种方法都可以从土壤中提取到分子量大于23.13 kb的DNA的片段,每克干土DNA的提取量为2.5~31μg,不同方法间在DNA产量、纯度等方面存在较大差异。     

马蹄金基因组DNA的提取方法比较

对马蹄金基因组DNA的提取方法———快速提取法、小量提取法和大量提取法进行了对比分析,结果表明,利用快速提取法可在20 min内快速可靠地从马蹄金(Dichondra repensForst.)组织中提取DNA,与小量提取法和大量提取法获得的DNA用于PCR检测结果一致,可为转基因植物的快速检测提供方法。     

提取北方土壤真菌DNA的一种方法

由于土壤理化性质的复杂性和真菌细胞壁结构的特殊性,从土壤样品中提取真菌基因组DNA比较困难.中国北方土壤与其它地区土壤相比有其自身的特点,因此,有必要优化一种适合于北方土壤真菌DNA提取的方法.本实验向灭菌黑土中分别投加12种在系统分类上差别较大的真菌,以传统土壤总DNA提取方法及纯菌DNA提取方法为基础,分别与蜗牛酶,纤维素酶进行组合、优化,得到7种不同的土壤真菌基因组DNA提取方法.利用真菌28S rDNA通用引物U1/U2-GC PCR-DGGE分析方法分别考察了7种不同方法所提取土壤真菌基因组DNA的多样性和代表性.结果表明:1)液氮研磨,纤维素酶、蜗牛酶和溶菌酶(浓度分别为6 、3和1 mg·ml-1)37 ℃作用60 min,2% SDS于65 ℃裂解30 min;2)-65 ℃～65 ℃冻融3次,纤维素酶、蜗牛酶和溶菌酶(浓度分别为6、3和1 mg·ml-1)37 ℃作用180 min,2%SDS于65 ℃裂解30 min的组合具有较好的提取效果.利用后一种方法分别对3种理化性质差异较大的中国北方自然土壤样品真菌DNA进行提取并分析,表明所提取土壤基因组DNA真菌特异性PCR-DGGE图谱条带丰富,该方法可用于多种北方土壤真菌多样性研究.     

FBH1 Helicase Disrupts RAD51 Filaments in Vitro and Modulates Homologous Recombination in Mammalian Cells

Efficient repair of DNA double strand breaks and interstrand cross-links requires the homologous recombination (HR) pathway, a potentially error-free process that utilizes a homologous sequence as a repair template. A key player in HR is RAD51, the eukaryotic ortholog of bacterial RecA protein. RAD51 can polymerize on DNA to form a nucleoprotein filament that facilitates both the search for the homologous DNA sequences and the subsequent DNA strand invasion required to initiate HR. Because of its pivotal role in HR, RAD51 is subject to numerous positive and negative regulatory influences. Using a combination of molecular genetic, biochemical, and single-molecule biophysical techniques, we provide mechanistic insight into the mode of action of the FBH1 helicase as a regulator of RAD51-dependent HR in mammalian cells. We show that FBH1 binds directly to RAD51 and is able to disrupt RAD51 filaments on DNA through its ssDNA translocase function. Consistent with this, a mutant mouse embryonic stem cell line with a deletion in the FBH1 helicase domain fails to limit RAD51 chromatin association and shows hyper-recombination. Our data are consistent with FBH1 restraining RAD51 DNA binding under unperturbed growth conditions to prevent unwanted or unscheduled DNA recombination.     

Distributions of Topological States in Circular DNA

A distinctive feature of closed circular DNA molecules is their particular topological state, which cannot be altered by any conformational rearrangement short of breaking at least one strand. This topological constraint opens unique possibilities for experimental studies of the distributions of topological states created in different ways. Primarily, the equilibrium distributions of topological properties are considered in the review. It is described how such distributions can be obtained and measured experimentally, and how they can be computed. Comparison of the calculated and measured equilibrium distributions over the linking number of complementary strands, equilibrium fractions of knots and links formed by circular molecules has provided much valuable information about the properties of the double helix. Study of the steady-state fraction of knots and links created by type II DNA topoisomerases has revealed a surprising property of the enzymes: their ability to reduce these fractions considerably below the equilibrium level.     

Topoisomerase II Regulates the Maintenance of DNA Methylation

The maintenance of DNA methylation in nascent DNA is a critical event for numerous biological processes. Following DNA replication, DNMT1 is the key enzyme that strictly copies the methylation pattern from the parental strand to the nascent DNA. However, the mechanism underlying this highly specific event is not thoroughly understood. In this study, we identified topoisomerase IIα (TopoIIα) as a novel regulator of the maintenance DNA methylation. UHRF1, a protein important for global DNA methylation, interacts with TopoIIα and regulates its localization to hemimethylated DNA. TopoIIα decatenates the hemimethylated DNA following replication, which might facilitate the methylation of the nascent strand by DNMT1. Inhibiting this activity impairs DNA methylation at multiple genomic loci. We have uncovered a novel mechanism during the maintenance of DNA methylation.     

The DDN Catalytic Motif Is Required for Metnase Functions in Non-homologous End Joining (NHEJ) Repair and Replication Restart

Metnase (or SETMAR) arose from a chimeric fusion of the Hsmar1 transposase downstream of a protein methylase in anthropoid primates. Although the Metnase transposase domain has been largely conserved, its catalytic motif (DDN) differs from the DDD motif of related transposases, which may be important for its role as a DNA repair factor and its enzymatic activities. Here, we show that substitution of DDN⁶¹⁰ with either DDD⁶¹⁰ or DDE⁶¹⁰ significantly reduced in vivo functions of Metnase in NHEJ repair and accelerated restart of replication forks. We next tested whether the DDD or DDE mutants cleave single-strand extensions and flaps in partial duplex DNA and pseudo-Tyr structures that mimic stalled replication forks. Neither substrate is cleaved by the DDD or DDE mutant, under the conditions where wild-type Metnase effectively cleaves ssDNA overhangs. We then characterized the ssDNA-binding activity of the Metnase transposase domain and found that the catalytic domain binds ssDNA but not dsDNA, whereas dsDNA binding activity resides in the helix-turn-helix DNA binding domain. Substitution of Asn-610 with either Asp or Glu within the transposase domain significantly reduces ssDNA binding activity. Collectively, our results suggest that a single mutation DDN⁶¹⁰ → DDD⁶¹⁰, which restores the ancestral catalytic site, results in loss of function in Metnase.     

Human HEL308 localizes to damaged replication forks and unwinds lagging strand structures

HEL308 is a superfamily II DNA helicase, conserved from archaea through to humans. HEL308 family members were originally isolated by their similarity to the Drosophila melanogaster Mus308 protein, which contributes to the repair of replication-blocking lesions such as DNA interstrand cross-links. Biochemical studies have established that human HEL308 is an ATP-dependent enzyme that unwinds DNA with a 3' to 5' polarity, but little else is know about its mechanism. Here, we show that GFP-tagged HEL308 localizes to replication forks following camptothecin treatment. Moreover, HEL308 colocalizes with two factors involved in the repair of damaged forks by homologous recombination, Rad51 and FANCD2. Purified HEL308 requires a 3' single-stranded DNA region to load and unwind duplex DNA structures. When incubated with substrates that model stalled replication forks, HEL308 preferentially unwinds the parental strands of a structure that models a fork with a nascent lagging strand, and the unwinding action of HEL308 is specifically stimulated by human replication protein A. Finally, we show that HEL308 appears to target and unwind from the junction between single-stranded to double-stranded DNA on model fork structures. Together, our results suggest that one role for HEL308 at sites of blocked replication might be to open up the parental strands to facilitate the loading of subsequent factors required for replication restart.     

Studies on human DNA polymerase epsilon and GINS complex and their role in DNA replication

In eukaryotic cells, DNA replication is carried out by the coordinated action of three DNA polymerases (Pols), Pol α, δ, and ε. In this report, we describe the reconstitution of the human four-subunit Pol ε and characterization of its catalytic properties in comparison with Pol α and Pol δ. Human Pol ε holoenzyme is a monomeric complex containing stoichiometric subunit levels of p261/Pol 2, p59, p17, and p12. We show that the Pol ε p261 N-terminal catalytic domain is solely responsible for its ability to catalyze DNA synthesis. Importantly, human Pol (hPol) ε was found more processive than hPol δ in supporting proliferating cell nuclear antigen-dependent elongation of DNA chains, which is in keeping with proposed roles for hPol ε and hPol δ in the replication of leading and lagging strands, respectively. Furthermore, GINS, a component of the replicative helicase complex that is composed of Sld5, Psf1, Psf2, and Psf3, was shown to interact weakly with all three replicative DNA Pols (α, δ, and ε) and to markedly stimulate the activities of Pol α and Pol ε. In vivo studies indicated that siRNA-targeted depletion of hPol δ and/or hPol ε reduced cell cycle progression and the rate of fork progression. Under the conditions used, we noted that depletion of Pol ε had a more pronounced inhibitory effect on cellular DNA replication than depletion of Pol δ. We suggest that reduction in the level of Pol δ may be less deleterious because of its collision-and-release role in lagging strand synthesis.     

A procedure for large-scale isolation of RNA-free plasmid and phage DNA without the use of RNase

A preparative procedure for the large-scale isolation of plasmid DNA without the use of RNAse is described. Crude plasmid DNA is prepared using a standard boiling method. High-molecular-weight RNA is removed by precipitation with LiCl, and low-molecular-weight RNA is removed by sedimentation through high-salt solution. The procedure is inexpensive, rapid, simple, and particularly suitable for processing several large-scale preparations simultaneously. A similar procedure has been developed for preparation of lambda-phage DNA.     

Formation of a stable RuvA protein double tetramer is required for efficient branch migration in vitro and for replication fork reversal in vivo

In bacteria, RuvABC is required for the resolution of Holliday junctions (HJ) made during homologous recombination. The RuvAB complex catalyzes HJ branch migration and replication fork reversal (RFR). During RFR, a stalled fork is reversed to form a HJ adjacent to a DNA double strand end, a reaction that requires RuvAB in certain Escherichia coli replication mutants. The exact structure of active RuvAB complexes remains elusive as it is still unknown whether one or two tetramers of RuvA support RuvB during branch migration and during RFR. We designed an E. coli RuvA mutant, RuvA2(KaP), specifically impaired for RuvA tetramer-tetramer interactions. As expected, the mutant protein is impaired for complex II (two tetramers) formation on HJs, although the binding efficiency of complex I (a single tetramer) is as wild type. We show that although RuvA complex II formation is required for efficient HJ branch migration in vitro, RuvA2(KaP) is fully active for homologous recombination in vivo. RuvA2(KaP) is also deficient at forming complex II on synthetic replication forks, and the binding affinity of RuvA2(KaP) for forks is decreased compared with wild type. Accordingly, RuvA2(KaP) is inefficient at processing forks in vitro and in vivo. These data indicate that RuvA2(KaP) is a separation-of-function mutant, capable of homologous recombination but impaired for RFR. RuvA2(KaP) is defective for stimulation of RuvB activity and stability of HJ·RuvA·RuvB tripartite complexes. This work demonstrates that the need for RuvA tetramer-tetramer interactions for full RuvAB activity in vitro causes specifically an RFR defect in vivo.     

Contribution of the intrinsic curvature to measured DNA persistence length

The persistence length of DNA, a, depends both on the intrinsic curvature of the double helix and on the thermal fluctuations of the angles between adjacent base-pairs. We have evaluated two contributions to the value of a by comparing measured values of a for DNA containing a generic sequence and for an "intrinsically straight" DNA. In each 10 bp segment of the intrinsically straight DNA an initial sequence of five bases is repeated in the sequence of the second five bases, so any bends in the first half of the segment are compensated by bends in the opposite direction in the second half. The value of a for the latter DNA depends, to a good approximation, on thermal fluctuations only; there is no intrinsic curvature. The values of a were obtained from measurements of the cyclization efficiency for short DNA fragments, about 200 bp in length. This method determines the persistence length of DNA with exceptional accuracy, due to the very strong dependence of the cyclization efficiency of short fragments on the value of a. We find that the values of a for the two types of DNA fragment are very close and conclude that the contribution of the intrinsic curvature to a is at least 20 times smaller than the contribution of thermal fluctuations. The relationship between this result and the angles between adjacent base-pairs, which specify the intrinsic curvature, is analyzed.